ES2328783T3 - SHOCK ABSORBER DEVICE FOR MICROWAVE OVEN. - Google Patents

Abstract

A damping device in a microwave oven including: an air duct (110) on an electrical compartment side of a partition wall to guide an air flow from a cooling fan (33) to a cooking chamber (20); a damper (120) rotatably articulated in the air duct (110) to selectively block the air duct (110); and control means for controlling the rotation of a driving eccentric (130), characterized in that the damping device further includes: a driving eccentric (130) having a relative thickness difference between a thick portion (131) and a thin portion (132) by having a curved upper surface having different heights left / right as seen from the front, where the driving eccentric is rotatable and is in contact with one end (121) of the damper (120) to press the end (121 ) of the damper (120) to rotate the damper (120) centered on the hinge (H) due to the difference in thickness; and an elastic body (160) to keep the driving eccentric (130) and the end (121) of the shock absorber (120) in contact.

Description

Damping device for oven microwave.

Background of the invention Field of the Invention

The present invention relates to an oven microwave, and more specifically, to a damping device in a microwave oven to regulate an air flow to a chamber of cooking.

Background of the related technique

The microwave oven is a device to disturb a series of water molecules in food by means of a microwave as a source of heat, in order to generate heat produced by friction between the molecules, to cook the food. The microwave oven has a convection function in the that the food is cooked, or a surface of the food is golden by the heat of a heater, together with the oven function microwave. As shown in Figure 1, the microwave oven it is provided with a body 10, a cooking chamber 20 in a lateral body portion 10 for cooking, a compartment electric 30 on the other side portion of the body to mount several components needed to move the device, and a wall divider 40 to divide the cooking chamber and compartment electrical 30. The electrical compartment 30 is provided with a magnetron 31 to generate a microwave, a transformer 32 to transform a mains voltage to a voltage required for the magnetron, a cooling fan 33 to cool the magnetron, and an air duct 34 to guide an air flow produced by the rotation of the cooling fan to a through hole (see 41 in Figure 2A) in partition wall 40 to the cooking chamber. And, there is a heater (not shown) for generate heat when the convection function is selected.

Meanwhile, during cooking using the convection function when cooking is done using heat from the heater, the microwave oven cannot properly perform the convection function since the fan air flow of cooling 33 reaches the cooking chamber 20 through the air duct 34 and the temperature of the chamber decreases 20 cooking heated by the heater. In order to block the air flow from cooling fan 33 to the chamber of cooking 20, a damping device is described in the Patent Korean number 99-35944 for selective blocking of air duct

As depicted in Figures 2A and 2B, the damping device described in Korean Patent Number 99-35944 is fitted with a shock absorber 51 mounted rotatably in the air duct 34 to block the flow of air into the cooking chamber, and a bidirectional motor 52 mounted in the air duct and coupled with the damper to rotate the damper 51. There is also a microswitch 53 mounted on a side of the air duct 34 to provide a control signal to a microcomputer (not shown) for the control operation of the bidirectional motor 52, a push button 54 protruding from a end of damper 51 to press the microswitch when the damper rotates, and a stop 55 mounted on a hole side through 41 of the dividing wall inside the air duct for Stop the rotation of the shock absorber.

The operation of the device will be explained front shock absorber

First, as depicted in the figure 2A, in a convection mode, a regular direction rotation (clockwise rotation) of damper 51 by the bidirectional motor 52 until its end 51a is stopped by the stop 55, blocks the air duct 34. Then, the shock absorber block the air duct so that the air flow cannot reach the cooking chamber 20, thereby retaining the heat of the heater inside the cooking chamber. And, at the moment when the air duct 34 is blocked by the shock absorber 51, with the Push button 54 the microswitch 53 is pressed, supplied to the microcomputer a signal generated at this time, to stop the bidirectional motor operation 52.

Second, as depicted in the Figure 2B, in a microwave mode, the damper 51 is rotated in a reverse direction (rotation in one direction to the left) by the bidirectional motor 52, to open the air duct 34. According to this, the air flow from the cooling fan 33 moves in the air duct, enters the cooking chamber 20 a through the through hole 41 in the dividing wall 40, and away from the microwave oven the cooking chamber steam 20. And, when the air duct 34 opens when the shock absorber 51 is moved, the Push button 54 is released from microswitch 53, and supplied to the microcomputer (not shown) a signal generated in this example, and the microcomputer for the bidirectional motor 52.

However, said damping device of The related technique has the following problems.

First, in the damping device related technique, the contact of the push button 54 with an actuator 53a in the microswitch 53 during the rotation of the shock absorber can cause a force to be supplied excessive to actuator 53a or noise generated. That is, with reference to figure 2A, it is known that the degree of compression of the actuator 53a depends on a mounting position of the stop 55, given that there may be manufacturing errors between the components, including the push button 54 on the shock absorber 51, the stop 55 in the dividing wall 40. For example, if the stop 55 is mounted more next to the through hole 41 due to an error of manufacturing, the shock absorber 51 stops before the button button 54 press actuator 53a, which makes the bidirectional motor control. However, since the damping device is inoperative if the bidirectional motor does not can be controlled, the stop is generally mounted in one position away from the side of the through hole. Consequently, since the damping device stops after the push button excessively press the actuator (see a dashed line in Figure 2A), excessive pressure may be supplied to the microswitch 53. In addition, since several components of coupling are mounted on different elements for use at control the operation of the bidirectional motor 52, the possibility of that excessive pressure is supplied to microswitch 53 is more high after assembly. That is, the manufacturing error in the mounting the partition wall 40 in which the stop 55 is mounted, the damper 51 on which the push button 54 is mounted, and the air duct 34 on which the microswitch 53 is mounted can make the possibility higher. Consequently, the pressure excessive on the microswitch 53 may cause problems, not only in the operation of microswitch operation proper, but also in the appearance of noise, or in the duration of microswitch 53, due to excessive contact between the push button 54 and the microswitch 53.

Second, the engine assembly bidirectional 52 on top outside the air duct 34 in the damping device of the related art is limited by an oven lamp (not shown) and a box superior 11 for reasons of space, which prolongs the process of assembly, and impoverishes interchangeability with other components of large dimensions, which results in a high cost.

Third, the direct coupling of damper 51 with bidirectional motor 52 in the device related art damper sets a direction of damper rotation only by the engine. That is, the rotation in the regular direction of the shock absorber requires a rotation in the regular direction of the motor, and a rotation in the reverse direction of the shock absorber requires a reverse direction rotation of the engine; you can use not the motor, but the bidirectional motor. He use of the bidirectional motor 52 results in a high cost and a system complicated.

US 4,450,344 describes an oven combined microwave and electric heater including a system fan to cool a magnetron, and a shock absorber for selectively introduce a forced air flow generated by the fan system to an oven cavity.

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Summary of the Invention

A damping device such as the set forth in claim 1.

Accordingly, the present invention is refers to a damping device in a microwave oven that substantially one or more of the problems due to limitations and disadvantages of the related technique.

An object of the present invention is provide a damping device in a microwave oven, which It has a smooth operation and a low cost.

Another object of the present invention is provide a damping device in a microwave oven, which It can eliminate excessive pressure on the microswitch.

Features and advantages will be presented Additional of the invention in the following description, and in part will be evident from the description or can be known by the setting In practice of the invention. The objectives and other advantages of the invention will be carried out and achieved with the structure indicated in particular in the written description and its claims as well as in the attached drawings.

To achieve these and other advantages and according to the Purpose of the present invention, as performed and described widely, the buffer device in a microwave oven includes an air duct on one side of electrical compartment of a dividing wall to guide a flow of air from a cooling fan to a cooking chamber, a shock absorber rotatably articulated in the air duct to block selectively the air duct, an eccentric drive which has a relative thickness difference between a thick portion and a thin, rotating portion in contact with one end of the damper to press the end of the damper to rotate the hinge centered damper due to the difference in thickness, and control means to control the rotation of the eccentric drive.

It should be understood that both the description previous general as the following detailed description are exemplary and explanatory and are intended to provide a further explanation of the claimed invention.

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Brief description of the drawings

The accompanying drawings, which are included for offer a greater understanding of the invention and incorporate and They are part of this specification, illustrate embodiments of the invention and together with the description serve To explain the principles of the invention:

In the drawings:

Figure 1 illustrates a perspective view disassembled from a microwave oven related technique.

Figure 2A illustrates a sectional view of a key part of a damping device of the related art In a convection mode.

Figure 2B illustrates a sectional view of a key part of a damping device of the related art In a microwave mode.

Figure 3A illustrates a sectional view of a key part of a damping device in a convection mode according to a preferred embodiment of the present invention.

Figure 3B illustrates a sectional view of a key part of a damping device in a microwave mode according to a preferred embodiment of the present invention.

Figure 4 illustrates a sectional view a through an I-I line in Figure 3B.

And Figure 5 illustrates a perspective view. of an eccentric of the present invention.

Detailed description of the preferred embodiment

Reference will now be made in detail to the preferred embodiments of the present invention, of which They illustrate examples in the accompanying drawings. In the explanation of the present invention, the components identical to the technique related will receive identical names and reference symbols, and Your detailed explanation will be omitted.

With reference to the figures 3A-5, the damping device in an oven microwave according to a preferred embodiment of the present invention includes an air duct 110 in an electrical compartment (see 30 in Figure 1) to guide an air flow produced by the rotation of a cooling fan 33 to a chamber of cooking 20, a shock absorber 120 rotatably articulated in the air duct for selective blocking of the air duct, a eccentric drive 130 having a thickness difference relative between a thick portion 131 and a thin portion 132, rotating in contact with one end 121 of the damper to press the end 121 of the shock absorber to rotate the shock absorber centered on the hinge due to the difference in thickness, and means control to control the eccentric rotation of drive As shown in Figure 5, the eccentric of drive 130 is cylindrical as a whole, preferably with a upper surface curved so that it has different thicknesses left / right as seen ahead (in the direction "TO"). And, as depicted in Figure 3A, the means of control preferably include a motor 140 coupled to the eccentric drive 130 with an axis to move the eccentric drive, a microswitch 150 to provide a electrical signal to the microcomputer (not shown) to stop / set  engine running selectively, and contacts 131a and 132a protruding from an outer circumference of the eccentric of drive so that they match the microswitch to Turn on / off the microswitch.

In this example, of course, the engine 140 It may or may not be a bidirectional motor; it is preferable that the engine 140 be unidirectional, because the damping device of the The present invention allows using the unidirectional motor that is low cost and that excludes the need to use the engine bidirectional That is, although the damping device of the related technique has a system in which the direction of rotation of the shock absorber (see 51 in figure 2A) is inverted only by means of the bidirectional motor (see 52 in figure 2A), given that the damping device of the present invention can change the direction of rotation of the damper using the portion thick 131 and thin portion 132, a difference in thickness of the eccentric drive, although the motor rotates only in one steering due to a separate drive eccentric 130 between the shock absorber 120 and the engine 140, there is no reason to use the bidirectional motor of high cost.

Next to this, as depicted in the figures 4 and 5, it is preferable that contacts 131a and 132a protrude respectively of left / right sides of the eccentric of drive 130 with reference to a front of the eccentric drive 130 (a portion that can be seen in the address "A" in figure 5), for positive motor control 140 which rotates the drive eccentric. I mean, how do I know represents in figure 3A, in convection mode, end 121 of the damper 120 remains located in the thin portion 132 of the eccentric drive stopping the eccentric rotation actuator at the moment the contact 131a on the side of the thick portion 131 of the drive eccentric presses the microswitch 150, and, as opposed to this, as represents in figure 3B, in microwave mode, end 121 of the damper 120 remains located in the thick portion of the eccentric drive stopping the eccentric rotation of actuation at the moment the contact 132a on the side of the Thin portion 132 of the drive eccentric presses the microswitch 150. Thus, it is preferable that the contacts are arranged respectively in the thick portion and the thin portion, the left / right sides of the eccentric drive. Y, as depicted in Figures 3A and 3B, it is preferable to arrange a elastic body 160 to connect one end of the shock absorber 120 and one side of the air duct 110 to maintain contact between the eccentric drive 130 and end 121 of the shock absorber providing an elastic force to the end 121 of the shock absorber. And, although not represented, a lane can be formed at one end of the damper and a guide groove has been formed in a upper surface of the eccentric drive, for insert the rail into the guide groove to make the eccentric drive 130 and the end 121 of the shock absorber contact. A specific reason that the drive eccentric 130 and the end 121 of the shock absorber have to maintain contact one with another is that, although the shock absorber 120 is rotated by a force of thrust of the thick portion when the thick portion 131 of the eccentric drive is moved towards end 121 of shock absorber because the thick portion is placed higher than the end of the shock absorber, the shock absorber 120 does not rotate because no force is exerted on the end of the shock absorber when the portion fine 132 of the eccentric drive is moved towards the end 121 of the damper because the thin portion is placed more lower than the end of the shock absorber, allowing the end of the shock absorber and the upper surface of the eccentric of drive away from each other. Therefore, it is necessary that the shock absorber end keep in touch with the surface upper eccentric drive when thin portion 132 of the eccentric drive moves towards end 121 of the shock absorber, for inversion of the shock absorber 120. And, as represented in figures 3A and 3B, the damping device of the The present invention also preferably includes a hole 111 in a required portion of the air duct to avoid interference between the end of the shock absorber and the conduit of air 110 when the damper rotates, and a support bracket 170 mounted outside the air duct near its mounting hole the eccentric drive 130 on its inner surface and the 140 engine on its outer surface. Together with these, as is represented in figures 3A and 3B, the damping device of the The present invention preferably further includes a stop 180 mounted on partition wall 40 to stop the damper when the damper blocks the air duct 110.

The operation of said device will be explained buffer of the present invention.

First, with reference to Figure 3A, in convection mode, when motor 140 is set to operation, the drive eccentric 130 is rotated, the end 121 of the shock absorber on the upper surface of the eccentric drive is moved down (the direction of the dashed line arrow in figure 3A) due to a thickness difference of the eccentric drive, and the other end 122 of the shock absorber is turned up (the direction of the continuous line arrow in figure 3B) centered on the axis of hinge H. And when the motor keeps turning until the contact 131a in the thick portion 131 of the drive eccentric press the microswitch 150, an electrical signal generated in the microswitch is transmitted to the microcomputer (no represented), to stop the engine, while the end of the shock absorber reaches the thin portion 132 of the eccentric of drive As shown in Figure 3A, the shock absorber 120 blocks the air duct 110, with its other end 122 stopped at stop 180, to block the air flow of the fan of cooling 33 to the cooking chamber 20, thereby facilitating the chamber heater heat loss prevention cooking due to air flow, previously.

Second, as depicted in the Figure 3B, in microwave mode, when motor 140 is set to operation, the eccentric drive 130 rotates, and the end 121 of the shock absorber located on the upper surface of the eccentric drive is moved up (the direction of the dashed line arrow in figure 3B) due to the difference Thickness of the eccentric drive, while the other end 122 of the shock absorber is moved down (the direction of continuous line in figure 3B) centered on hinge axis H. Y when the motor continues to rotate until contact 132a in the Thin portion 132 of the drive eccentric comes to press the microswitch 150, the electrical signal generated in the microswitch is transmitted to the microcomputer (not shown), to stop the engine and the end of the damper rest in the thick portion 131 of the drive eccentric. In this example, as shown in Figure 3B, the shock absorber 120 opens the air duct 110, facilitating the air flow of the cooling fan 33 to the cooking chamber 20, to move away steam and odors from the cooking chamber from the oven microwave.

As explained, since the device damper in a microwave oven of the present invention facilitates the use of a directional motor and improves a structure of contact to press the microswitch using the eccentric of drive, the damping device has the advantages following.

First: the 150th actuator in the Microswitch can be pushed with a regular force. Is say, although the error produced by a structural problem in the damping device related technique make the button push button excessively press the microswitch, the device buffer of the present invention can prevent the appearance of noise due to excessive contact pressure on the actuator in the microswitch, since the damping device of the The present invention has a structure in which the contacts to the left / right of the eccentric drive Press the microswitch when the motor turns.

Second: spatial limitation can be avoided of the next components.

Although the two-way motor of the technique related mounted outside the upper portion of the duct air has a spatial limitation of the oven lamp, the box above, and the like, as the engine of the present invention is not mounted outside the upper / lower portion of the duct of air, but on one side of the air duct, the space can be used to the fullest.

Third: the unit cost of the device.

Although the damping device in the art related requires a bi-directional motor, the device damper of the present invention allows even the engine to be used Unidirectional, which can reduce the unit cost.

The advantages include all effects described in the detailed description of the preferred embodiment of The present invention.

It will be apparent to those skilled in the art that you can make several modifications and variations on the device damper in a microwave oven of the present invention without depart from the scope of the invention. Thus, the This invention covers the modifications and variations of this invention provided that they fall within the scope of the annexed claims.

Claims (7)

1. A damping device in an oven microwave including: an air duct (110) on one side of electrical compartment of a dividing wall to guide a flow of air from a cooling fan (33) to a cooking chamber (20); a damper (120) rotatably articulated in the air duct (110) to selectively block the air duct (110); Y control means for controlling the rotation of a driving eccentric (130), characterized in that the damping device further includes: an eccentric drive (130) having a difference in relative thickness between a thick portion (131) and a thin portion (132) for having a curved upper surface that It has different heights left / right as seen ahead, where the eccentric drive is rotating and is in contact with one end (121) of the shock absorber (120) to press the end (121) of the shock absorber (120) to rotate the shock absorber (120) centered on the hinge (H) due to the difference in thickness; Y an elastic body (160) to maintain the eccentric drive (130) and end (121) of shock absorber (120) in contact. 2. A damping device according to the claim 1, wherein the driving eccentric (130) is cylindrical together. 3. A damping device according to the claim 1, wherein the control means includes; a motor (140) coupled to the eccentric of drive (130) to move the drive cam (130); a microswitch (150) to provide a electrical signal to the microcomputer for stop / start-up motor selective (140); Y contacts (131a, 132a) that protrude from outer circumferential surfaces of the eccentric of drive (130) to couple with the microswitch (150) to Turn on / off the microswitch (150). 4. A damping device according to the claim 3, wherein the motor (140) is an engine unidirectional 5. A damping device according to the claim 3, wherein the contacts (131a, 132a) protrude from the eccentric drive (130) on its left / right sides with reference to its front. 6. A damping device according to the claim 1, further including: a hole (111) formed in the air duct (110); Y a support bracket outside the air duct (110) near the hole (111) that has an interior in which the drive eccentric (130) is mounted, and a exterior on which the motor is mounted (140). 7. A damping device according to the claim 1, further including a stop (180) mounted on the partition wall to stop the damper (120) when the damper blocks the air duct (110).